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Rutgers University Chenren Xu Joint work with Bernhard Firner , Yanyong Zhang

Improving RF-Based Device-Free Passive Localization In Cluttered Indoor Environments Through Probabilistic Classification Methods. Rutgers University Chenren Xu Joint work with Bernhard Firner , Yanyong Zhang Richard Howard, Jun Li, Xiaodong Lin. Passive Localization. Motivation

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Rutgers University Chenren Xu Joint work with Bernhard Firner , Yanyong Zhang

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  1. Improving RF-Based Device-Free Passive Localization In Cluttered Indoor Environments Through Probabilistic Classification Methods Rutgers University ChenrenXu Joint work with Bernhard Firner, Yanyong Zhang Richard Howard, Jun Li, Xiaodong Lin

  2. Passive Localization • Motivation • Indoor challenge • Proposed solution • Experimental methodology • Performance evaluation • Conclusion and future work

  3. RF-Based Localization Active Localization

  4. RF-Based Localization

  5. RF-Based Localization Passive Localization

  6. Passive Localization • Motivation • Indoor challenge • Proposed solution • Experimental methodology • Performance evaluation • Conclusion and future work

  7. Why Passive Localization? • Monitor indoor human mobility Elder/health care

  8. Why Passive Localization? • Monitor indoor human mobility Detect traffic flow

  9. Why Passive Localization? • Monitor indoor human mobility • Health/elder care, safety • Detect traffic flow • Provides privacy protection • No identification • Use existing wireless infrastructure

  10. Passive Localization • Motivation • Indoor challenge • Proposed solution • Experimental methodology • Performance evaluation • Conclusion and future work

  11. Multipath Effect

  12. Multipath Effect

  13. Multipath Effect

  14. Cluttered Indoor Scenario

  15. Cluttered Indoor Scenario A user steps across one Line-of-Sight

  16. Cluttered Indoor Scenario A user steps across one Line-of-Sight RSS fluctuates in a unpredictable fashion

  17. Cluttered Indoor Scenario The RSS change can either go up to 12 dBm

  18. Cluttered Indoor Scenario Or go down to -12 dBm

  19. Cluttered Indoor Scenario These two peak points can have 24 dB difference in energy within only 2 meters.

  20. Cluttered Indoor Scenario Deep fade We also observe that these two points within 0.2 m can have 15 dB difference.

  21. Cluttered Indoor Scenario

  22. Cluttered Indoor Scenario

  23. Cluttered Indoor Scenario

  24. Passive Localization • Motivation • Indoor challenge • Proposed solution • Experimental methodology • Performance evaluation • Conclusion and future work

  25. Proposed Solution • High dimensional space • Measure radio signal strength (RSS) changes in multiple transmitter and receiver links. Link T1 – R1 Link T2 – R2

  26. Proposed Solution • High dimensional space • Cell-based localization • Flexible precision • Classification approach

  27. Linear Discriminant Analysis • RSS measurements with user’s presence in each cell is treated as a class k • Each class k is Multivariate Gaussian with common covariance • Linear discriminant function: Link 2 RSS (dBm) k = 1 k = 2 k = 3 Link 1 RSS (dBm)

  28. Proposed Solution • High dimensional space • Cell-based localization • Lower radio frequency • Smooth the spatial variation

  29. Frequency Impact RSS changes smoother on 433.1 MHz than on 909.1 MHz

  30. Frequency Impact Less deep fading points!

  31. Proposed Solution • High dimensional space • Find features with fewer deep fading points • Cell-based localization • Average the deep fading effect • Lower radio frequency • Reduce the deep fading points Mitigate the error caused by the multipath effect!

  32. Passive Localization • Motivation • Indoor challenge • Proposed solution • Experimental methodology • Performance evaluation • Conclusion and future work

  33. Experimental Deployment Total Size: 5 × 8 m

  34. Experimental Deployment

  35. System Parameters

  36. System Description • Hardware: PIP tag • Microprocessor: C8051F321 • Radio chip: CC1100 • Power: Lithium coin cell battery (~1 year) • Protocol: Unidirectional heartbeat (Uni-HB) • Packet size: 10 bytes • Beacon interval: 100 millisecond

  37. Training Methodology • Case A: stand still at the each cell center • Measurement only involves center of the cell • Ignore the deep fade points • Case B: random walk within each cell • Measurement includes all the space • Average the multi-path effects Training only takes 15 mins!

  38. Passive Localization • Motivation • Indoor challenge • Proposed solution • Experimental methodology • Performance evaluation • Conclusion and future work

  39. Metrics • Cell estimation accuracy • The ratio of successful cell estimations with respect to the total number of estimations. • Average error distance • Average distance between the actual location and the estimated cell’s center.

  40. Localization Accuracy • Cell estimation accuracy: 97.2 % cell estimation accuracy with 0.36 m average error distance

  41. Reducing Training Dataset Only 8 samples are good enough 8 100

  42. Robust to Link Failure 5 transmitter + 3 receivers = 90% cell estimation accuracy

  43. Long-term Stability

  44. Multiple Subjects Localization

  45. Larger Deployment Total Size: 10 × 15 m Cell Size: 2 × 2 m 13 transmitters and 9 receivers

  46. Larger Deployment Cell estimation accuracy: 93.8% Average error distance: 1.3 m

  47. Passive Localization • Motivation • Indoor challenge • Proposed solution • Experimental methodology • Performance evaluation • Conclusion and future work

  48. Conclusion and Future Work • Conclusion • We propose a general probabilistic classification framework to solve the passive localization problem with: • High accuracy, low cost, robust and stable • Multiple subjects tracking generalization • Future work • Improving multiple people tracking • Passively detect the number of people

  49. Q & A Thank you

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